Classifications

• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
  • A61B6/00—Apparatus or devices for radiation diagnosis; Apparatus or devices for radiation diagnosis combined with radiation therapy equipment
  • A61B6/42—Arrangements for detecting radiation specially adapted for radiation diagnosis
  • A61B6/4208—Arrangements for detecting radiation specially adapted for radiation diagnosis characterised by using a particular type of detector
  • A61B6/4258—Arrangements for detecting radiation specially adapted for radiation diagnosis characterised by using a particular type of detector for detecting non x-ray radiation, e.g. gamma radiation
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
  • A61B6/00—Apparatus or devices for radiation diagnosis; Apparatus or devices for radiation diagnosis combined with radiation therapy equipment
  • A61B6/02—Arrangements for diagnosis sequentially in different planes; Stereoscopic radiation diagnosis
  • A61B6/03—Computed tomography [CT]
  • A61B6/037—Emission tomography
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
  • A61B6/00—Apparatus or devices for radiation diagnosis; Apparatus or devices for radiation diagnosis combined with radiation therapy equipment
  • A61B6/42—Arrangements for detecting radiation specially adapted for radiation diagnosis
  • A61B6/4208—Arrangements for detecting radiation specially adapted for radiation diagnosis characterised by using a particular type of detector
  • A61B6/4233—Arrangements for detecting radiation specially adapted for radiation diagnosis characterised by using a particular type of detector using matrix detectors
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
  • A61B6/00—Apparatus or devices for radiation diagnosis; Apparatus or devices for radiation diagnosis combined with radiation therapy equipment
  • A61B6/42—Arrangements for detecting radiation specially adapted for radiation diagnosis
  • A61B6/4291—Arrangements for detecting radiation specially adapted for radiation diagnosis the detector being combined with a grid or grating
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
  • A61B6/00—Apparatus or devices for radiation diagnosis; Apparatus or devices for radiation diagnosis combined with radiation therapy equipment
  • A61B6/44—Constructional features of apparatus for radiation diagnosis
  • A61B6/4417—Constructional features of apparatus for radiation diagnosis related to combined acquisition of different diagnostic modalities
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
  • A61B6/00—Apparatus or devices for radiation diagnosis; Apparatus or devices for radiation diagnosis combined with radiation therapy equipment
  • A61B6/44—Constructional features of apparatus for radiation diagnosis
  • A61B6/4429—Constructional features of apparatus for radiation diagnosis related to the mounting of source units and detector units
  • A61B6/4435—Constructional features of apparatus for radiation diagnosis related to the mounting of source units and detector units the source unit and the detector unit being coupled by a rigid structure
  • A61B6/4441—Constructional features of apparatus for radiation diagnosis related to the mounting of source units and detector units the source unit and the detector unit being coupled by a rigid structure the rigid structure being a C-arm or U-arm
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
  • A61B6/00—Apparatus or devices for radiation diagnosis; Apparatus or devices for radiation diagnosis combined with radiation therapy equipment
  • A61B6/52—Devices using data or image processing specially adapted for radiation diagnosis
  • A61B6/5205—Devices using data or image processing specially adapted for radiation diagnosis involving processing of raw data to produce diagnostic data
• • G—PHYSICS
  • G01—MEASURING; TESTING
  • G01T—MEASUREMENT OF NUCLEAR OR X-RADIATION
  • G01T1/00—Measuring X-radiation, gamma radiation, corpuscular radiation, or cosmic radiation
  • G01T1/16—Measuring radiation intensity
  • G01T1/1603—Measuring radiation intensity with a combination of at least two different types of detector
• • G—PHYSICS
  • G01—MEASURING; TESTING
  • G01T—MEASUREMENT OF NUCLEAR OR X-RADIATION
  • G01T1/00—Measuring X-radiation, gamma radiation, corpuscular radiation, or cosmic radiation
  • G01T1/16—Measuring radiation intensity
  • G01T1/161—Applications in the field of nuclear medicine, e.g. in vivo counting
  • G01T1/1615—Applications in the field of nuclear medicine, e.g. in vivo counting using both transmission and emission sources simultaneously
• • G—PHYSICS
  • G06—COMPUTING; CALCULATING OR COUNTING
  • G06T—IMAGE DATA PROCESSING OR GENERATION, IN GENERAL
  • G06T11/00—2D [Two Dimensional] image generation
  • G06T11/003—Reconstruction from projections, e.g. tomography
• • G—PHYSICS
  • G21—NUCLEAR PHYSICS; NUCLEAR ENGINEERING
  • G21K—TECHNIQUES FOR HANDLING PARTICLES OR IONISING RADIATION NOT OTHERWISE PROVIDED FOR; IRRADIATION DEVICES; GAMMA RAY OR X-RAY MICROSCOPES
  • G21K1/00—Arrangements for handling particles or ionising radiation, e.g. focusing or moderating
  • G21K1/02—Arrangements for handling particles or ionising radiation, e.g. focusing or moderating using diaphragms, collimators
  • G21K1/025—Arrangements for handling particles or ionising radiation, e.g. focusing or moderating using diaphragms, collimators using multiple collimators, e.g. Bucky screens; other devices for eliminating undesired or dispersed radiation

Definitions

• the invention relates to the detection of x-ray and gamma quanta. It finds application in the medical field, more particularly in the fields of medical imaging and medical interventions, and may be used for example to provide an x-ray image and a corresponding nuclear image of a region of interest.
• the x-ray image typically provides structural information indicative of the anatomy of the region of interest.
• the nuclear image defined herein to mean an image indicative of radiotracer distribution in an object, is generated based on detected gamma quanta.
• the nuclear image may for example be a gamma scintigraphy or a SPECT image and typically provides functional, or physiological information relating to the region of interest. Together the two different image types can be used to improve the identification of an underlying pathology during a medical investigation.
• SIRT selective internal radiation therapy
• a number of workflow steps are required in order to prevent potential side effects. These steps may include the closure of atypical lung and gastrointestinal shunts before injection of Yttrium-90 -containing microspheres. This prevents radiation ulcers which might otherwise be triggered by extra-hepatic localization of administered micro-spheres.
• catheter-based vessel coiling is performed under x-ray guidance during a minimally- invasive procedure. Afterwards, the remaining shunt level towards lungs and gastrointestinal area may be controlled by injection of
• Tc-labeled MAA Technetium 99m Tc albumin aggregated, i.e. Tc-labeled MAA, into both main liver arteries followed by planar gamma imaging. During this procedure the patient is typically repeatedly transported between a cath lab and SPECT imaging room.
• Document US2013/237818A1 discloses a radiation detector having a first detector layer and a second detector layer.
• Detectors of the first layer include scintillators and light detectors.
• the detectors of the second detector layer include scintillators and optical detectors.
• the scintillators of the first layer have a smaller cross-section than the scintillators of the second layers.
• a group of the first layer scintillators overlay each second group scintillator.
• detectors of the first layer detect transmission radiation to generate a CT image with a relatively high resolution and the detectors of the second layer detect PET or SPECT radiation to generate nuclear data for reconstruction into a lower resolution emission image.
• Document US6448559B1 discloses a detector assembly for multi-modality PET/SPEC/CT scanners.
• the detector assembly comprises a first layer for detecting low energy gamma radiation and x-rays and a second layer for detecting high energy gamma radiation.
• the first layer is generally transparent to high energy gamma radiation.
• the detector assembly includes a photodetector in the form of an avalanche photodiode to transform the light signals from the scintillators into electric signals.
• the detector assembly may be incorporated in a multi-modality PET/SPECT/CT scanner for simultaneous transmission and emission imaging with the same detection geometry.
• a collimator is positioned in front of the detector assembly to define preferential incidence directions for SPECT photons.
• the combined imaging detector is adapted for simultaneous detection of gamma and x-ray quanta.
• the combined imaging detector includes an x-ray anti-scatter grid, a layer of x-ray scintillator elements for generation of x-ray scintillation light signals in response to detected x-ray quanta, and a first photodetector array configured to receive the x- ray scintillation light signals and to convert said x-ray scintillation light signals into a first group of electrical signals.
• the combined imaging detector also includes a layer of gamma scintillator elements for generation of gamma scintillation light signals in response to detected gamma quanta, and a second photodetector array configured to receive the gamma scintillation light signals and to convert said gamma scintillation light signals into a second group of electrical signals.
• the x-ray anti-scatter grid, the layer of x-ray scintillator elements, the first photodetector array, the layer of gamma scintillator elements, and the second photodetector array are arranged in a stacked configuration along a radiation- receiving direction.
• the x-ray anti-scatter grid comprises a plurality of septa that define a plurality of apertures which are configured to collimate both x-ray quanta and gamma quanta received from the radiation receiving direction such that received gamma quanta are collimated only by the x-ray anti-scatter grid.
• a gamma camera i.e. a camera that is used to provide a SPECT image or a scintigraphy image
• a gamma camera collimator is a device that is used to limit the angular range of gamma photons that are ultimately detected by the camera. In so doing it ensures that each point in the image corresponds to a unique point in the source.
• it is attached to the front surface of the gamma camera and is formed from thousands of precisely-aligned holes in a gamma-absorbing material.
• the holes, i.e. apertures are thus defined by walls, i.e.
• septa that are formed from the gamma-absorbing material and operate to limit the angular view of each gamma detector that is positioned behind the collimator.
• the gamma-absorbing material is typically lead, and the collimator is usually formed by casting or folding lead foil.
• the lead septa have a depth along the radiation receiving direction, this depth being conventionally determined by the energy of the gamma quanta that the gamma camera is designed to detect.
• septa with a depth of 20 - 42 mm are typically used and this accounts for some 30 - 50 kg of the weight of a SPECT collimator.
• An x-ray anti-scatter grid includes a grid arrangement of septa that define apertures that limit the number of scattered x-ray quanta that are detected by an x-ray detector.
• ID and 2D anti-scatter grids may be used for this purpose, the former comprising a ID array of walls, or septa; the latter comprising a 2D array of such septa.
• an x-ray anti-scatter grid limits a detector's field of view to x-ray quanta having paths that are substantially parallel to the septa.
• a ID anti-scatter grid can be used to limit the x-ray detector field of view to a plane, and a 2D anti-scatter grid can be used to limit the field of view to a line.
• a ID anti-scatter grid is conventionally considered to provide adequate anti-scatter performance in x-ray imaging.
• an x-ray anti-scatter grid is also typically formed from lead, but in contrast its septa typically have a depth in the radiation receiving direction of some 1 - 5 mm; a depth used in conjunction with 70 keV x-rays.
• received gamma quanta are collimated only by the x-ray anti-scatter grid. Since a gamma camera collimator is omitted, the combined imaging detector is much lighter than, for example, the combined weight of an x-ray detector and a SPECT detector. Consequently the mounting and positioning of the combined detector is greatly simplified.
• the combined detector becomes sufficiently lightweight to be attached to a conventional c-arm.
• the combined imaging detector includes a reconstruction unit.
• the reconstruction unit is configured to generate a reconstructed nuclear image based on the second group of electrical signals.
• the reconstruction unit is configured to generate the reconstructed nuclear image based on a point spread function, PSF, model that represents the gamma scintillation light signal distribution for each aperture of the x-ray anti-scatter grid.
• PSF point spread function
• the reconstruction unit is configured to generate a reconstructed nuclear scintigraphy image from a measured nuclear scintigraphy image.
• the reconstruction unit is further configured to generate the reconstructed nuclear scintigraphy image by subtracting a background pixel value, i.e. a reference pixel value, from pixel values in the measured nuclear scintigraphy image.
• a background pixel value i.e. a reference pixel value
• Fig. 1 illustrates a first embodiment of a combined imaging detector 110 that is adapted for simultaneous detection of gamma and x-ray quanta.
• Fig. 2 illustrates a portion of a 2D x-ray anti-scatter grid 211 that is formed from two crossed ID anti-scatter grids 217 x and 217 y .
• Fig. 3 illustrates a combined imaging detector 310 in combination with a reconstruction unit 321 that is configured to generate a reconstructed nuclear image.
• Fig. 4 illustrates three simulated point spread functions in arbitrary units for a ID x-ray anti-scatter grid for three different source- ASG ranges, z.
• Fig. 6 illustrates various method steps that may be used in combination with the combined imaging detector during an iterative reconstruction process to generate a SPECT image.
• the present invention provides a system for providing both a nuclear image and an x-ray image of a region of interest. Thereto a combined imaging detector is provided.
• Fig. 1 illustrates a first embodiment of a combined imaging detector 110 that is adapted for simultaneous detection of gamma and x-ray quanta.
• the combined imaging detector includes an x-ray anti-scatter grid 111, a layer of x-ray scintillator elements 112 for generation of x-ray scintillation light signals in response to detected x-ray quanta, and a first photodetector array 113 configured to receive the x-ray scintillation light signals and to convert said x-ray scintillation light signals into a first group of electrical signals.
• the first group of electrical signals may be output by means of x-ray data bus 119.
• the combined imaging detector further includes a layer of gamma scintillator elements 114 for generation of gamma scintillation light signals in response to detected gamma quanta, and a second photodetector array 115 configured to receive the gamma scintillation light signals and to convert said gamma scintillation light signals into a second group of electrical signals.
• the second group of electrical signals may be output by means of gamma data bus 120.
• the x-ray anti-scatter grid 111, the layer of x-ray scintillator elements 112, the first photodetector array 113, the layer of gamma scintillator elements 114, and the second photodetector array 115 are arranged in a stacked configuration along a radiation-receiving direction 116.
• Combined detector 110 is thus configured to receive gamma and x-ray radiation from radiation-receiving direction 116.
• Radiation-receiving direction 116 is perpendicular to a plane comprising any of items 111, 112, 113, 114, 115.
• X-ray anti-scatter grid 111 comprises a plurality of septa 117A, B, C that define a plurality of apertures 118 which are configured to collimate both x-ray quanta and gamma quanta received from radiation receiving direction 116 such that received gamma quanta are collimated only by the x-ray anti-scatter grid 111.
• the combined detector benefits from a significant weight reduction owing to the use of x-ray anti-scatter grid 111 as an anti-scatter grid for the x-ray quanta and as a collimator for the gamma quanta. Furthermore, the combined detector provides simultaneous detection of x-ray and gamma quanta, and the resulting x-ray and nuclear images are self-registered.
• an x-ray anti-scatter grid differs from a gamma camera collimator primarily in that the septa of an x-ray anti-scatter grid have a much shorter depth than the septa of a gamma camera collimator along radiation receiving direction 116.
• the depth of the septa along radiation receiving direction 116 for an x- ray anti-scatter grid is typically approximately 1/10 th of that for a gamma camera collimator. This reduction alone gives rise to a corresponding weight reduction in the combined detector.
• each septum 117A,B,C in the plurality of septa has a depth Zdi along the radiation receiving direction 116 that is less than or equal to 5, or 4, or 3, or 2 millimeters.
• a gamma camera collimator has a septum thickness of between 150 microns and 1700 microns for the detection of 140 keV gamma quanta.
• each septum 117A,B,C in the plurality of septa has a thickness in a direction perpendicular to the radiation receiving direction 116 that is less than or equal to 100 microns, or less than or equal to 75 microns, or less than or equal to 50 microns, or less than or equal to 40 microns.
• These constraints on the septa thickness may be used as an alternative, or in addition to the above depth constraint to define x-ray anti-scatter grid 111.
• an x-ray anti-scatter grid conventionally includes only a ID array of septa. Such 'slits' that are provided by the septa adequately reduce scatter.
• a collimator for gamma imaging is typically formed from a 2D array of septa.
• a ID x-ray anti-scatter grid that comprises a first set of septa that extend only along a first direction (x)
• a 2D x-ray anti-scatter grid may be used as x-ray anti-scatter grid 111.
• an x-ray anti-scatter grid and a gamma camera collimator include i) that the septum pitch of an x-ray anti-scatter grid is typically smaller than the septum pitch in a gamma camera collimator and ii) that the apertures defined by the septa of an x-ray anti-scatter grid are conventionally in the form of slits whereas the apertures defined by the septa of a gamma collimator are typically circular or hexagonal and thus have rotational symmetry around radiation receiving direction 116 with an order exceeding 2, or are circularly symmetric.
• Exemplary x-ray anti-scatter grids include the N44 rl5 grid; i.e.
• the pitch of an x-ray anti-scatter grid may be less than or equal to 1 mm; and by contrast the pitch of a gamma camera collimator is conventionally greater than 1 mm.
• x-ray anti-scatter grid 111 as a collimator for received gamma quanta essentially provides slightly poorer collimation of received gamma photons as compared to a gamma camera collimator, and thus results in a slight degradation in nuclear image quality.
• the use of the x-ray anti-scatter grid as a collimator for the gamma camera results in a slightly elevated background signal in the nuclear image due to increased septal penetration from obliquely- incident gamma quanta.
• this slight degradation in nuclear image quality is acceptable for many nuclear imaging applications.
• a PSF describes a detector's response to gamma quanta originating from a point source at a predetermined source-collimator range. This is typically represented by a graphical plot of the detected gamma scintillation light as a function of distance from an axis passing through the source and the centre of the collimator, i.e. off-axis distance.
• the detected gamma scintillation light is recorded in a plane that is perpendicular to the axis. In such a plot, nuclear image resolution is determined in-part by the width of the PSF.
• FIG. 4 illustrates three simulated point spread functions in arbitrary units for a ID x-ray anti-scatter grid for three different source-ASG ranges, z.
• the simulation parameters were as follows: 44 line pair per cm anti-scatter grid with an interspace ratio of 15 (code: N44 rl5); lead ASG strip depth along the radiation receiving direction 2.87 mm; lead ASG strip width perpendicular to the radiation receiving direction 36 ⁇ ; i.e. a typical thickness for low line pair grids; septa pitch 216 microns, modified from the typical value of 227 microns to simplify simulation.
• the three PSF curves reveal a background signal in the order of 20 - 30% outside the Gaussian-shaped signal.
• the low- frequency ripples seen on all curves are due to single, twice, triple, etc. penetration of septa.
• the simulated spatial resolution for this x-ray anti-scatter grid when used as a SPECT collimator for 140 keV radiation (Tc-99m) is 7.34 mm, 9.06 mm, 13.38 mm FWHM for a corresponding source-
• x-ray anti-scatter grid 111 may alternatively be provided by a ID x-ray anti-scatter grid (211) that comprises a first set of septa that extend only along a first direction (x).
• Fig. 4 The simulated point spread functions illustrated in Fig. 4 were for a ID x-ray anti-scatter grid. Similar PSFs are also plotted for a 2D x-ray anti-scatter grid formed from two crossed ID anti-scatter grids such as anti-scatter grid 211 illustrated in Fig. 2, in Fig. 5.
• Fig. 2 illustrates a portion of a 2D x-ray anti-scatter grid 211 that is formed from two crossed ID anti-scatter grids 217 x and 217 y .
• a first set of septa 217 x extend along a first direction, x
• a second set of septa 217 y extend along a second direction, y.
• first set of septa 217 x and the second set of septa 217 y are arranged in a stacked configuration along radiation receiving direction 216 such that the first direction, x, and the second direction, y, are mutually transverse.
• Each septum in Fig. 2 has a depth Zd2 along radiation receiving direction 216.
• Fig. 5 One quadrant of the complete PSF for the gamma scintillation light distribution in a plane perpendicular to the radiation receiving direction is illustrated in Fig. 5.
• the x and y axes of Fig. 5 represent in millimetres the off-axis distance in orthogonal planes x and y, in the range 0 to 10 mm.
• the off-axis distance, x, in Fig. 5 labelled "x-DIST. / mm" thus corresponds to the off-axis distance in Fig. 4 labelled "DIST./ mm".
• the simulation parameters were the same as those in Fig. 4.
• Fig. 4 As compared to Fig. 4, in Fig.
• the crossed ASG offers improved spatial resolution.
• Fig. 5A and Fig. 5B each representing one quadrant of the whole planar PSF, indicate that without any additional processing, the projection images from point sources results in both a near-constant background signal overlaid with the typical 4-star pattern for rays parallel to the grid axes.
• the additional low- frequency ripple pattern in the PSF will largely average-out for typical SPECT image resolution during a subsequent nuclear image reconstruction process.
• each septum 217 x , 217 y in the plurality of septa has a depth Zd2 along radiation receiving direction 216 that is less than or equal to 5, or 4, or 3, or 2 millimeters.
• each septum 217 x , y in the plurality of septa may have a thickness in a direction perpendicular to the radiation receiving direction 216 that is less than or equal to 100 microns, or less than or equal to 75 microns, or less than or equal to 50 microns, or less than or equal to 40 microns.
• the septa of the two crossed ID x-ray anti-scatter grids in Fig. 2 can be combined in a single layer to provide a 2D array of septa in a single layer. The performance of such a single layer is expected to be much better than the performance of the ID and the 2D x-ray anti-scatter grids in Fig. 4 and Fig. 5 in terms of penetration through the septa.
• additional processing of the second electrical signals from the combined imaging detector, specifically those output at gamma data bus 120, may also be used based on the principles outlined above to further improve the quality of a subsequently- reconstructed nuclear image.
• Such processing is conventionally performed during image reconstruction by an image reconstruction unit.
• Fig. 3 illustrates a combined imaging detector 310 in combination with a reconstruction unit 321 that is configured to generate a reconstructed nuclear image.
• Combined imaging detector 310 corresponds to item 110 in Fig. 1 and is likewise configured to receive gamma and x-ray radiation from radiation-receiving direction 316.
• the nuclear image is generated based on the second group of electrical signals that are received from the second photodetector array by means of gamma bus 320.
• the image may subsequently be displayed by means of display device 322 that is optionally in communication with reconstruction unit 321.
• the form in which the PSF is accounted- for the image reconstruction process may depend to some extent on the type of nuclear image that is acquired.
• the image may for example be a scintigraphy image; i.e. an image acquired from a gamma detector in a fixed position, or a tomographic, i.e. a SPECT image, indicative of a cross section of an imaged object.
• a scintigraphy image i.e. an image generated during a planar image acquisition mode
• the non-zero portion of the PSF i.e. a background signal
• reconstruction unit 321 is configured to generate a reconstructed nuclear image based on a point spread function model that represents the gamma scintillation light signal distribution for each aperture 118, 218 of x-ray anti-scatter grid 111, 211.
• the gamma scintillation light signal distribution is modelled for a direction or a plane that is perpendicular to radiation receiving direction 316.
• the point spread function model used in the reconstruction process may include, in a direction perpendicular to radiation receiving direction 316, a central lobe portion and a non-zero portion beyond the central lobe.
• reconstruction unit 321 may be further configured to generate the reconstructed nuclear image by subtracting the non-zero portion from the point spread function. By accounting for the non-zero portion, i.e. the background portion of the PSF in this way, an improved nuclear image can be generated.
• this nonzero portion can be approximately 5 % to 30 % of the peak value of the PSF.
• a PSF is used in an image reconstruction process it is modelled as only a central lobe similar to the straight line in Fig. 4; i.e. there is no non-zero portion in the PSF model beyond the central lobe at all.
• the PSF may be applied in each loop of an iterative reconstruction process. Each time the loop is executed the noise in the resulting image is reduced.
• the PSF is preferably applied on the forward projected estimate of the spatial distribution of the radiotracer onto the detector.
• Fig. 6 illustrates various method steps that may be used in combination with the combined imaging detector during an iterative reconstruction process to generate a SPECT image.
• Fig. 6 illustrates various method steps that may be used in combination with the combined imaging detector during an iterative reconstruction process to generate a SPECT image.
• the reconstruction unit may be configured to generate a reconstructed nuclear image using an iterative reconstruction algorithm that includes the steps of:
• M2 the estimated radiotracer distribution onto the combined imaging detector to provide a projected estimated scintillation light distribution
• the estimated radiotracer distribution is typically projected onto a plane that includes second photodetector array 115.
• the instructions when executed on a processor cause the processor to generate a reconstructed SPECT nuclear image corresponding to an actual radiotracer distribution in a volume of interest using an iterative reconstruction algorithm based on the second group of electrical signals and based on a point spread function model that represents the gamma scintillation light signals for each septum in the plurality of septa, comprise the steps of:
• M2 the estimated radiotracer distribution onto the combined imaging detector to provide a projected estimated scintillation light distribution
• the computer program product may be provided by dedicated hardware as well as hardware capable of executing software in association with appropriate software.
• the functions can be provided by a single dedicated processor, by a single shared processor, or by a plurality of individual processors, some of which can be shared.
• explicit use of the term "processor” or “controller” should not be construed to refer exclusively to hardware capable of executing software, and can implicitly include, without limitation, digital signal processor "DSP” hardware, read only memory “ROM” for storing software, random access memory “RAM”, non-volatile storage, etc.
• embodiments of the present invention can take the form of a computer program product accessible from a computer-usable or computer-readable storage medium providing program code for use by or in connection with a computer or any instruction execution system.
• a computer-usable or computer readable storage medium can be any apparatus that may include, store, communicate, propagate, or transport the program for use by or in connection with the instruction execution system, apparatus, or device.
• the medium can be an electronic, magnetic, optical, electromagnetic, infrared, or semiconductor system, or apparatus or device, or a propagation medium.
• Examples of a computer-readable medium include a semiconductor or solid state memory, magnetic tape, a removable computer diskette, a random access memory "RAM”, a read-only memory “ROM”, a rigid magnetic disk and an optical disk.
• Current examples of optical disks include compact disk - read only memory "CD-ROM”, compact disk - read/write “CD-R/W”, Blu- RayTM and DVD.
• reconstruction unit 321 in Fig. 3 may be configured to generate a reconstructed nuclear scintigraphy image from a measured nuclear scintigraphy image.
• the measured nuclear scintigraphy image comprises a plurality of pixel values that are generated based on the second group of electrical signals.
• reconstruction unit 321 is further configured to generate the
• the reconstructed nuclear scintigraphy image by subtracting a background pixel value, i.e. a reference pixel value, from the pixel values in the measured nuclear scintigraphy image.
• a background pixel value i.e. a reference pixel value
• an improved nuclear image can be obtained.
• the subtraction may be performed either in the spatial or frequency domain.
• the reconstructed nuclear scintigraphy image corresponds to an object having a boundary
• the background pixel value is the value of a pixel in the measured nuclear scintigraphy image at a point beyond the boundary.
• the background pixel value i.e.
• the reference pixel value, that is subtracted may be an estimated value corresponding to a modelled or expected value, or the value of a pixel at or near the edge of the field of view of the gamma camera, for example within 20 or 10 or 5 pixels of the edge of the field of view.
• the background pixel value that is subtracted is, furthermore, preferably the value of a pixel in the measured nuclear scintigraphy image at a point beyond the boundary; i.e. the subtracted pixel position lies between the boundary and the edge of the field of view.
• the non- negativity signal constraint should be preserved.
• Example 1 Combined imaging detector (110) for simultaneous detection of gamma and x- ray quanta; the combined imaging detector comprising: an x-ray anti-scatter grid (111);
• a first photodetector array configured to receive the x-ray scintillation light signals and to convert said x-ray scintillation light signals into a first group of electrical signals;
• a second photodetector array configured to receive the gamma scintillation light signals and to convert said gamma scintillation light signals into a second group of electrical signals;
• the x-ray anti-scatter grid (111), the layer of x-ray scintillator elements (112), the first photodetector array (1 13), the layer of gamma scintillator elements (114), and the second photodetector array (115) are arranged in a stacked configuration along a radiation-receiving direction (116);
• the x-ray anti-scatter grid (111) comprises a plurality of septa (117A, B, C) that define a plurality of apertures (118) which are configured to collimate both x-ray quanta and gamma quanta received from the radiation receiving direction (116) such that received gamma quanta are collimated only by the x-ray anti-scatter grid (111).
• Example 2 The combined imaging detector of Example 1 wherein the x-ray anti-scatter grid (211) comprises a first set of septa (217x) that extend along a first direction (x), and a second set of septa (217y) that extend along a second direction (y);
• first set of septa (217x) and the second set of septa (217y) are arranged in a stacked configuration along the radiation receiving direction (116, 216) such that the first direction (x) and the second direction (y) are mutually transverse.
• Example 3 The combined imaging detector of any one of Examples 1 - 2 wherein i) each septum (117A,B,C, 217x, 217y) in the plurality of septa has a depth (zdl, zd2) along the radiation receiving direction (116, 216) and the depth (zdl, zd2) is less than or equal to 5 millimeters and/ or ii) each septum (117A,B,C, 217x, 217y) in the plurality of septa has a thickness (t2) in a direction perpendicular to the radiation receiving direction (116, 216) and the thickness (t2) is less than or equal to 100 microns.
• Example 4 The combined imaging detector of any one of Examples 1 - 3 further comprising a reconstruction unit (321) configured to generate a reconstructed nuclear image based on the second group of electrical signals;
• the reconstruction unit (321) is configured to generate the reconstructed nuclear image based on a point spread function model that represents the gamma scintillation light signal distribution for each aperture (118, 218) of the x-ray anti- scatter grid (1 11, 211).
• Example 5 The combined imaging detector of Example 4 wherein the point spread function model includes, in a direction perpendicular to the radiation receiving direction, a central lobe portion and a non-zero portion beyond the central lobe; and wherein the reconstruction unit is further configured to generate the reconstructed nuclear image by subtracting the non-zero portion from the point spread function.
• Example 6 The combined imaging detector of Example 4 or Example 5 wherein the reconstructed nuclear image is a SPECT image corresponding to an actual radiotracer distribution in a volume of interest and wherein the reconstruction unit is configured to generate the reconstructed nuclear image using an iterative reconstruction algorithm that includes the steps of:
• M2 the estimated radiotracer distribution onto the combined imaging detector to provide a projected estimated scintillation light distribution
• Example 7 The combined imaging detector of any one of Examples 1 - 3 further comprising a reconstruction unit (321) configured to generate a reconstructed nuclear scintigraphy image from a measured nuclear scintigraphy image comprising a plurality of pixel values, the measured nuclear scintigraphy image being generated based on the second group of electrical signals;
• the reconstruction unit (321) is further configured to generate the reconstructed nuclear scintigraphy image by subtracting a reference pixel value from the pixel values in the measured nuclear scintigraphy image.
• Example 8 The combined imaging detector of Example 7, wherein the reconstructed nuclear scintigraphy image corresponds to an object having a boundary;
• Example 9 The combined imaging detector of Example 7 or Example 8 wherein the combined imaging detector has a field of view for detected gamma quanta; and wherein the reference pixel value is the value of a pixel in the measured nuclear scintigraphy image at a point within 10 pixels of a pixel at the edge of the field of view.
• Example 10 The combined imaging detector of any one of Examples 7 - 9 wherein the subtracting is performed in the frequency domain.
• Example 11 comprising the combined imaging detector of any one of Examples 1 - 10.
• Example 12 Computer program product comprising instructions for controlling the combined imaging detector of any one of Examples 1 - 3; which instructions, when executed on a processor cause the processor to either:
• M2 the estimated radiotracer distribution onto the combined imaging detector to provide a projected estimated scintillation light distribution
• point spread function model is applied during the step of projecting the estimated radiotracer distribution
• ii) generate a reconstructed nuclear scintigraphy image from a measured nuclear scintigraphy image comprising a plurality of pixel values, the measured nuclear scintigraphy image being generated based on the second group of electrical signals, wherein the instructions comprise the step of:
• the combined imaging detector 110 is adapted for simultaneous detection of gamma and x-ray quanta.
• the combined imaging detector 110 includes an x-ray anti-scatter grid 111, a layer of x-ray scintillator elements 112, a first photodetector array 113, a layer of gamma scintillator elements 114, and a second photodetector array 115 that are arranged in a stacked
• the x-ray anti-scatter grid 111 comprises a plurality of septa 117A, B, C that define a plurality of apertures 118 which are configured to collimate both x-ray quanta and gamma quanta received from the radiation receiving direction 116 such that received gamma quanta are collimated only by the x-ray anti-scatter grid 111.

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